Selecting and printing mechanism



SELECTING AND PRINTING MECHANISM Filed March 20, 1929 6 Sheets-Sheet 1 L1. Q M S S J if S S 1.52 I a S j S S @9 1 av 129 w s I Q 1 o 1 156 A37 62 J6 24 n 7a 5 7 k 46 Z5 INVENTORJ' Sept. 1, 1931.

s. MORTON ET AL 1,821,110

SELECTING AND PRINTING MECHANISM Filed March 20, 1929 6 SheetsSheet P INVENTORJ ATTORNEYS Sept. 1, 1931. s. MORTON ET AL 1,821,110

SELECTING AND PRINTING MECHANISM Filed March 20, 1929 6 Sheets-Sheet 3 v 7 l: 106 g n 9 ATTORNEYJ Sept. 1, 1931.

S. MORTQN ET AL SELECTING AND PRINTING MECHANISM Filed Maich 20. 1929 6 Sheets-Sheet 4 Sept. 1,1931. 5. MORTON ET AL V SELECTING AND PRINTING MECHANISM Filed March 20, 1929 6 Sheets-Sheet 5 Qwuentow Jag/112 mm fiomml 47:01 1

[draw 1. Ilka/$044M z 1 WW S. MORTON ET AL SELECTING AND PRINTINGMECHANISM Sept. 1, 1931.

Filed March 20, 29 6 Sheets-Sheet 6 Patented Sept. 1, 1931 UNITED STATES PATENT-OFFICE- s'rmatmo MORTON; or CHICAGO, HOWARD L. mam. or KENILWORTH, 4ND EDWARD E. xLEINsoIIMID'r, or ram: RIDGE, ILLINOIS, ASSIGNORS 'ro TELETY'PE como- RATION, or cmcaeo, ILLINOIS, A CORPORATION or, DELAWARE SELECTING AND PRINTING MECHANISM:

' Application filed March" 20, 1929. Serial No. 343,612.

Our present invention relates to selecting and printing mechanisms and is especially suitable for printing telegraphs, but is also equally applicable to various other types. of

selective devices.

The recent increase in the volume of stock transactions in a fixed period of time'has made it necessary to use stock tickers, having a much higher speed of operation than that of the present tickers, so that the lag between a sale and its appearance on the tape may be a minimum; To produce a stock ticker that will operate at the desired high s ee'd and one magnet which operates in response to the received impulses to variably control the selective mechanism is preferably of the polarized type so that it may be opera-ted directly from the line signals without a relay and so that the signals used may be of alternating polarity rather than of current and no current intervals. Suchsignals give the maximum accuracy of reception.

In our invention, the magnet armature which controls the selecting mechanism mechanically is light, yet rigid, and is loi'ng so that its tip will have a large motion toeliminate'narrow margins and requirements for great accuracy of construction. The method of selection is such that the armature has an extremely small amount of {,work to perform and acts with respect to the selective mechanism merely to control the selection,

I the actual power for moving the elements of ing the character to be recorded, an recordthe selective mechanism being furnished by a local power drive.

Provision is also made for utilizing subas may be obtained by'a utilization of the stantially a full signal interval for osition-;

ing it. Accordingly, the positioning and printing of one character takes place while the nextsignal is operating the selecting device. Furthermore, the movement of the' .tape to produce the spaces between letters has been arranged to occupy as long an interval as ossible, so that the motion of the tape will be comparatively uniform and better adapt the high speed ticker to methods of projecting a magnified image of the tape on a screen for the use of customers of a brokerage house.

In order that high speed operation ma be obtained, an overlap has beenprovide by using two sets of selectors, the primary set being controlled by the incoming signals and the second set being controlled by the first set, and so arranged that the setting of all the first set is transferred at one time to the second set, whereupon'the first set is free too erate in response to a succeeding code, while t e second set has. almost the entire interval-of one signal to operate the character selecting and printing mechanism. We have also made provision to perform this transfer operation with a minimum amount of power and with v great rapidity. In addition, we have provided improved printing and tape feed mechanisms adapted tohigh speed operation with little jar. The power for performing these operations in our preferred form of rotating motor and in order to prevent noise and unnecessary strains, a novel clutch mechanism is provided. In order to operate our improved mechanisms at high speed, special provision is made in the useful life with a minimum of maintenance costs as well as to permit the manufacture by quantity production methods at low cost. Accordingly, a primary object of our invention is to provide novel, low cost, eflicient and invention is supplied from a continuously esign of arts to insure uninterrupted operation and ong,

durable selecting mechanisms and printing apparatus especially adapted to hi h speed operation and suitable for stock tic ers and other printing telegraph mechanisms.

Further ob ects of the invention'are such various combmatlons, subcombinations, and

principles hereinafter set forth and as are defined by the scope of the appended claims.

As shown by the drawings, Figure 1 is a plan view of a preferred embodiment of the invention in which the front part of the machine is shown at the right of the drawings.

-Figure 2 is a left side elevation with parts broken away of the form of invention shown in Figure 1.

Figure 3 is a front elevation thereof with some parts in section.

Figure 4 is a section on line H of Figure 3.

Figures 5 and 6 are detailed showings of the control for the circuits of the motor provided for supplying power to the printing mechanisms in the preferred embodiment of the invention.

Figure 7 isa detailed showing of the flutter lever and cam in the preferred embodiment of our invention.

Figure 8 is a circuit diagram employed in connection with a preferred embodiment of our invention.

Figures 9 and 10 are respectively top and side detail views illustrating the means on the stop arm on the typewheel shaft, for preventing chattering when the typewheel is stopped.

Figures 11 and 12 are circuit diagrams showing preferred forms of electrical connections.

Figures 13 and 14 are fragmentary side and ends views showing a modified form of flutter lever and flutter cam arrangement.

Figure 15 is a fragmentary side elevational view corresponding to Figure 2 disclosing the modified form of flutter lever in operative relation with the pin barrel and selector mechanism.

Figure 16 is a top plan view of the construction illustrated in Figure 15.

Figures 17 and 18 are fragmentary sectional views showing a modified arrangement of the selectors with latching means for holding the selectors in either operated position.

Figure 19 is a circuit diagram of a modified form of motor control and Figures 20 and 21 are fragmentary elevational views showing the mechanism em ployed in Figure 19.

Referring to Figure 1, our preferred mechanism is controlled by a single selector magnet which may be of any well known construction. As shown, the selector magnet is of a sensitive polarized type such as used in stock ticker operation and comprises a permanent U-shaped magnet 1, surrounding the pole pieces 2. Disposed between the pole pieces 2 are the magnet windings 3 and 4 which are energized in accordance with impulses received over a signalling line (not shown) to operate the armature 5. Armature 5 is pivotally supported on the armature bearing 5 in any conventional manner and has a protruding extension 6 formed on one end thereof. The motion of the armature 5 is limited by the adjustable screws 7, carried by the member 8 on the magnet 1 and adapted to separately engage the opposite sides of the inner end of the armature 5. As shown, a terminal block 8 of the usual construction is supported in any well known manner above the magnet coils 3 and 4 for marking the necessary circuit connections as will be explained more fully hereinafter.

As the magnet 1 energizes and deenergizes in accordance with marking and spacing impulses received over the signalling line, the extension 6 of armature 5 is moved into and out of the path of a flutter lever 9 shown in detail in Figure 7. The flutter lever 9 comprises two arms 10 and 11 arranged substantially at right angles to each other, the outer and of the arm 10 having a stop 12 formed thereon and adapted when the armature 5 is moved to the right to engage the extension 6 thereof. The flutter lever 9 is pivotally mounted on a pin 13 about which it is normally urged in a clockwise direction by spring 14, one end of which is secured to the frame and the other end to an extension 15 on the flutter lever 9. The other arm 11 of the flutter lever 9 terminates in a bifurcated jaw 16 having extensions or cam followers 17 and 18 formed thereon, the purpose of which is to be described hereinafter.

In operative relation with the bifurcated jaw 16 is the flutter cam 19 having a plurality of radially arranged right and left corrugations or apexes such as 20, 21 and 22 formed thereon and disposed at equal dis tances from the median plane thereof. The apex of each corrugation alternately engages either of the extensions or followers 17 or 18 of the bifurcated jaw 16 as the flutter cam 19 is moved by them in a manner to be described in detail hereinafter.

The flutter cam 19 is secured to and rotatable with a longitudinally slidable cam drum or pin barrel sleeve member 23, driven by a motor M as described hereinafter and having limit stops for its longitudinal movement. The motor M is of the usual construction and as will appear hereinafter may be either of the direct or alternating current type and is provided with rings 20 carried on the motor shaft over which brushes 21' held in position in block 22 by caps 23' wipe. As the flutter cam member 19 moves past projections 17 and 18, it will cause the flutter lever 9 to undergo either a clockwise or counterclockwise move ment about pivot 13. The spring 14 normally urges the flutter lever 9 in a clockwise direction and accordingly holds the flutter cam 19 and the pin barrel sleeve 23 against its right stop position. WVith the pin barrel member 23 at its extreme right position a left apex 21 of the flutter cam 19, as it moves past and engages projection 17, moves the flutter lever 9 counterclockwise carrying its stop 12 out of the path of armature 5. This condition is shown in Figure 7. As the inclined portion of the flutter cam; that is, the portion just preceding the right hand apex 22 passes through the jaw 16 of the flutter lever 9, the right. hand apex 22 engages projection 18 and rocks the lever 9 in a clockwise direction. If at that instant, the line signal is such that the armature 5 is in its left hand position, the complete motion of the flutter lever 9 will .be permitted and the pin barrel 23 will ac cordingly remain in its normal righthand position. If at such an instant, however, the signal receivedis such that'the armature 5 is in its right hand position, the stop 12 of the flutter lever 9 will engage with the projection 6 on the armature 5. The movement of the flutter lever 9. will accordingly be arrested. Inasmuch as lever 9 cannot move the flutter cam 19 it will be forced to the left as its right apex 22 passes the extension or follower 18. In this manner the pin barrel sleeve 23 will be moved to the right or'left in accordance with' the received spacing or marking impulses.

As will be clear to those skilled in the art, all of the movements of the in barrel sleeve 23 is accomplished substantially entirely by power supplied by the motor M driving the pin barrel; that is, not only is the power for rotatin the pin barrel 23 supplied from this origina source, but due to the shaping of the flutter cam 19, the rotational power is translated into a linear movement for moving the pin barrelfsleeve 23 to the right or left,

although this movement is controlled by the line magnet. Except therefore for releasing the clutch in response to a start impulse'there is a minimum requirement of power from the line magnet, the solerequirementof the line current duringthe signalling period, being to move the armature 5 which is free from any encumbrance such as in the case of a relay. The receiving line magnet may therefore be of a very delicate structure responsive to very small currents and having a mini'' mum of inertia and may therefore operate at a very high speed. Inasmuch as the local source of-power supplymay be of any value within practical limits, the pin barrel 23 may rotate and move longitudinally at a very high speed.

It will be noted that normally the pin barrel sleeve 23 is maintained in its extreme right hand position as the follower 17 engages the left hand apex 21 due to the spring 14 which normally rocks the flutter "lever 9 in a 'clockwiseidirection and'which is made ofsuflicient power to force the-pin barrel to its right hand position. It will, of course, be

understood that the pin barrel is rotated at a speed whichis in synchronism with the speed 17 holds the projection 12 of the flutter lever 9 out of the path of the stop 6, leaving the armature free to operate.

As the right hand apex 22 engages the follower 18 and tends to rock the flutter lever 9 in a clockwise direction with the aid of spring 14, the projection 6 of the armature 5 depending on the character of the received impulse, will either be in or out of the path of projection 12.

From the above description, it will be noted that the flutter lever 9 acts as a combined flutter lever and spring lever for the pin barrel 23, inasmuch as the spring 14 provides the energy which, acting through the follower 17, forces the pin barrel 23 to the right in response to a spacing impulse. During the rotation of the pin barrel 23 and in response to a marking impulse which moves armature 5 to the right sothat projection 6 is in the path of stop 12, the follower 17 engages and follows the corrugation at the projection 21 by the action of spring 14 until stop 12 engages the projection 6 on the armature 5 whereupon further movement of the flutter lever 9 is arrested. An instant later the outwardly sloping portion of the projection engages the follower 18 and as aresult of further rotation of cam 19 the pin'barrel'23 is moved to the left.

In order to provide a smooth and even spring tension on the pin barrel selector, the combined flutter lever construction disclosed is replaced by two independent levers one of which functionsasa flutter lever to engage the flutter 'cam andthe other of which functions as the spring lever to supply the uniform and smooth spring tension onthe pin barrel. This modification is disclosed in Figures 13 to 16 in whichsimilar characters are employed for the same 'parts' as in the with an arm -11 which terminates in bifurcated jaw 16 having extension cam f0l-,

Ill

lowers 17 and 18 formed thereonfthe purpose of which has been described above.- "In operative relation with the bifurcatedjaw 16 is-the fluttercam 1.9 having a plurality of radially arranged right and left corrugations or apexes such as 20, 21 and 22 formed thereon and disposed at equal distances from the median plane thereof. The apex of eachcorrugation alternately engages either of the extensions or followers 17 or 18of the bifurcated jaw '16, as theflutter cam 19 is moved past them in a manner described.

A second lever 21' is pivotally mounted on the pin 13 and normally moves in a clockwise direction thereabout by a spring 22, one end of which is secured to the lever 21 and the other end to the frame work in any suitable manner. Lever 21 is provided with a tooth or follower 23 which rides over the smooth surface 24' of the cam 19 adjacent to the cam barrel 23 under action of the spring 22.

As described inconnection with the first modification, the flutter cam 19 carried by the pin barrel 23 is rotated thereby, and barrel 23 is rotated by motor M. Normally the spring 22 will move the lever 21 clockwise about the pivot pin 13. The projection 23' on the lever 21 engages the apex 21 as the flutter cam 19 rotates and forces the pin harrel 23 to its right hand position. As the flutter cam 19 continues to rotate the follower 23 follows the corrugations on the flutter cam 19 rocking the lever 21 alternately counterclockwise and then clockwise. Simultaneously as the followers 18 and 17 successively engage the projections on the flutter cam 19, the flutter lever 9 is rocked first clockwise and then counterclockwise about the pin 13. This will be the condition of operation during the spacing impulse intervals when the armature 5 is in its left hand position and without the path of the stop 12.

In response, however to a marking impulse, the armature 5 as described above moves to the right and into the path of the stop 12. At this instant, the follower 18 engages the projection 22 on the flutter cam 19. Due to the obstruction in the path of stop 12, the lever 9 cannot rock and accordingly the flutter cam 19 and pin barrel 23 must move to the left as the cam 19 rotates. Simultaneously the follower 23' of the lever 21 is following the corrugations of the flutter cam 19 by action of its spring 22'. As the flutter lever 19 moves to the left, it rocks the lever 9 coun terclockwise about its pivot 13. If during the next impulse interval a spacing impulse is i received, the armature 5 is moved to the left releasing the stop 12 and the spring 22 will thereupon rock the lever 21 clockwise about its pivot 13 and through the surface on bar rel 23 will move the flutter cam 19 to the right as described above. It will be clear from the above description that the follower 23 will keep the spring pressure from wearlng one side of the flutter cam and maintain even pressure by eliminating the bumping action of a spring lever.

In order to insure synchronousoperation, the pin barrel sleeve 23 is rotated on the start-stop principle, the start and stop impulses controlling the rotation of the selector cam drum or pin barrel 23 in unison with the remote transmitting distributor (not shown) which is transmitting thecode combinations of impulses to which the K printer is responsive. I By this unison of 0poration, the character signals sent out by the transmitter may be properly received by the selecting mechanism and translated into letters and characters as will be described.

The transmission of the start impulse, in the present case, being a spacing impulse, the pin barrel selector is normally held against rotation. To this end there is connected with the selector cam drum 23, a selector cam stop arm 24, Figure 4, arranged to engage a stop lug 25 which may be carried on the frame of the apparatus in any well known manner but is preferably carried by an orientation adjustment as will be described hereinafter. The engagement of the stop arm 24 with the stop lug 25 occurs only when the selector cam drum or pin barrel is in its left hand position. This condition is obtained when the pin barrel sleeve 23 having rotated to a position at which stop arm 24 engages lug 25 a marking impulse is receivedf In response to a marking impulse at this instant, the armature 5 is moved to its right hand position and as the flutter lever 9, is rocked clockwise by the right hand apex 22 engaging the follower 18, the armature 5 and flutter lever 9 engage as described above and the flutter cam 19 is moved to the left, moving the selector cam drum or pin barrel 23 in a similar direction until the stop arm 24 engages stop lug 25. Engagement of these two prevents rotation of sleeve 23 as will be described. This is the normal stop condition. A received spacing impulse will rock the armature 5 to the left releasing thereby the flutter lever 9. Spring 14 now moves the flutter lever '9 and through flutter cam 19 shifts the selector cam drum or pin barrel 23 to the right withdrawing stop arm 24 from engagement with a stop lug 25.

The selector cam drum or pin barrel 2 is now rotated by motor M as will now be described. As shown in Figure 4, the sleeve 23 is loosely mounted on a main shaft 26 rotatively mounted in anti-friction bearings 27 and 28 supported on the spaced upwardly extending brackets 29 and 30 of the frame of the ticker, the rear end portion of the shaft 26 of reduced diameter having keyed thereto in any desired manner, a flanged bush- .ing 31.

Secured to the flange of bushing 31 by screws 30 is a worm gear 32 in meshing engagement with a worm 34 mounted on the shaft of the motor M. A nut 33 and lock nut 33' on the shaft 26 retains the bushing 31 and gear 32 in position.

The forwardly extending end of the shaft 26 which is also of reduced diameter carries a sleeve 35 retained in position by the nuts 35 and on which the selector cam drum or pin barrel 23, flutter cam 19 and selector cam stop 24 are adapted to slide.

Mounted on the shaft 26 between bracket .30 and the selector cam drum 23 .is a friction clutch 36 comprising a flanged-sleeve member 37 keyed to the shaft 26 in any conbetween which a friction member 40 as for example a felt disc is placed, a similarfric- 19 tion member 40 being positioned between the drive disc 38 and the flanged portion of the sleeve member 37 The plate 39 is engaged by the slit annular spring 41 which presses against the disc 42 in threaded engagement with the end of the sleeve member 37 and held in position by-means of the nut 43, the

' tension of the spring 41 being regulated by the disc 42 and locknut 43.

As will now be clear, the friction'mechanism may be removed as avunit without 9.1- tering the adjustments. The drive disc 38 which is driven by the motor M, through shaft 26 and flanged sleeve 37 at all times is in operative relation with the selector cam drum 23 throughthe medium of the selector cam stop arm 24. When the selector cam drum 23 is in its left stop position as described above, the selector cam stop arm 24 engages the stop lug 25 and as a result the drive we 38 will sli with respect to the rotating sleeve member 3 and the selector cam drum is sta-, tionary. The stop arm 24 has a horizontal portion which passes through a slot 38 in selector friction disc 38 so that when this disc rotates, thedrum 23 rotates with it.

In response to a start impulse, sleeve 23 is moved to the right, as described above and the selector cam stop arm 24 is moved out of engagement with the stop lug 25. The selector cam drum 23 is thereupon rotatively driven through sleeve 37. In this manner the transmission of a starting or spacing impulse starts the selector drum revolving.-

The speed of rotation of the selector cam Yflutterlever 9. The two will thereupon en gage as described above and move the drum plete revolution and stop arm 24 is in opera.- tive relation with stop lu 25 and when the drum is moved to the le the two engage bringing the drum to a stop. i

drum 23 is such that when the transmitting.

. to the left or stop position. At this period in the revolution, the drum has made a-cm- In thepresent case, the selector cam drum 23 is geared to rotate one twelfth faster than the transmitter,-;\ but it is so constructed that the distance from the osition where it can receive one im ulse an wherejt can receive the next impu se is one'twelfth greater than the distance Where the transmitting distributor can send one itself and. the next. This difference in speed between the selector cam drum 23and the transmitting distributor is provided in order to insure that the selector drum will return to its normal stop positionbefore the transmitting distributor. As will be noted from the above description, the transmittin distributor transmits the start impulse which controls the starting of rotation of the selector cam drum. Accordingly if the selector cam drum shouldreach its normal position, after the transmission of the start impulse andafter the transmitting distributor has started rotating, the drum would come to a stop as it would not at that instant receive/the start impulse. Thus, it is essential that the selector cam drum reach its normal osition before the transmitting distributor in order that it may tionto receive an impulse.

The only alternative would be to maintain be in condi- I the two units at exactly the same speed which in practice has been found to be impossible as in a short time even a slight difference-would cause the transmitting. distributor and receiving mechanism to fall out of step so that when the transmittin distributor was sending out the first impu e of a character signal,jthe selector cam drum might be in a position to receive the second impulse. By rotating the selector cam drum slightly faster than the transmittin distributor, the former completes its revol tions somewhat sooner than the transmittin distributor. .In order to correct for this, ifierence in speed, the selecting positions of the cam drum are spread further apart than are the transmitting positions ofthe distributor. Thus if the transmittin grees from the rst to the second transmitting position,-the selector cam drum is arranged to travel 48% degrees in traveling from the first to the second selecting position.

distributor travels 45 de Inasmuch however as the selectorcam drum travels one twelfthfasterfit will reach its second selecting position at the same time that will be a slighterror in each selectin position the mechanism is so constructe provide for thls and due to the fact that the asto selector cam drum starts its revolution inthe unison with the transmitting distributor this error never becomes very large.

From the above description, it will be .clear that the relative position of the cam drum 23 with respect to the received signals is Very important inasmuch as the drum must be at a position such that the stop arm 24 engages stop lug 25 before the start signal is received and must be in proper position to receive the message code impulses. This is in art taken care of by adjusting the speed 0 rotation. It is however also important to start the rotation at a predetermined position of the cam drum 23.

To this end, an orientation plate 44 having a code is mounted on bracket 30 carrying the stop lug 25 directly behind the selector cam frictionclutch 36. Carried on the plate 44 is a thumb nut 45; the turning of which moves the orientation plate and with it the stop lug 25. To take an orientation range a test sentence such as The quick brown fox., etc. is transmitted to the printer continually while the range is being taken. While this sentence is being received the orientation scale is shifted by the thumb nut toward zero until errors begin to appear in the test sentence. Then it is moved back slowly until these errors disappear. This position indicates one limit of the orientation range. The same performance is repeated toward the opposite end of the scale and the other limit is found. After the two limits or extreme positions of perfect printing have been found the orientation scale is set midway between these two points.

The selector cam drum 23 comprises a hollow cylinder with twelve selector cams 45- projecting from its outer surface. Six of these cams are marking cams and six are spacing cams.

Associated with each pair of selectoncams 45'; that is, a pair comprising a spacing and a marking selector cam, is one of six selector levers 46, Figure 3, pivotally mounted on a shaft 52 suitably carried by the stock ticker frame, and on the same horizontal center line as shaft 26. Each of said levers 46 com prises arms 48 and 49 located respectively above and below the selector cam drum 23. The ends of the arms 48 and 49 are offset with respect to each other, the lower or marking arm 49 being ofi'set toward the back and upper or spacing arm 48 being offset toward the front of the printer. This is done so that when the marking camjndividual to this particular selector lever lines up with the arm 49, the spacing cam individual thereto will pass to the rear of the spacing arm 48 and when the spacing cam is in line with the spacing arm 48, the marking cam will pass .0 the front of the marking arm.

Accordingly, in response to a marking impulse, theselector cam drum 23 is moved to left as described above, the extension 49 of the selector lever 46 will be engaged by the associated cam 45, and the spacing cam will pass by the extension 48. As a result of the engagement of the cam 45 with the extension 49, the selector 46 is rocked about its pivot 52 in a counterclockwise direction. On the other hand, in response to a spacing impulse the selector cam drum 23 will be moved to the right hand position, as described above and the cam individual to the selector 46 will engage the arm extension 48 rocking the selector lever 46 in a clockwise direction about the pivot 52. In this manner the selector levers 46 are set in one or the other of its positions in accordance with the received code. As will be described more fully hereinafter, the first five selector levers are operated in accordance with code combinations of impulses to make a selection and the sixth selector lever operates in response to a sixth or shift pulse to select letters or numerals.

These selector levers are carried in a selector lever unit or guide 50 located to the right of the selector cam drum 23 which functions to hold the selector levers 46 in position so that they can be moved to either the spacing up position or marking down position by the selector cams 45 as described above. slots 51 in the guide 50, Figures 1 and 3, a spring 52' being inserted in the slot with The selector levers are mounted in each selector lever 46 against the side of the slot to assure that it will remain well placed by the action of the corresponding cam 45'. These selector levers, it will be noted, have no normal position but remain set in either operated position until the impulse in a succeeding code is such as to shift it to the opposite position. Inasmuch as they have no normal position, very little power is necessary to operate them and the number of operations is reduced as they do not operate until a change in the code signal is received.

A's explained in the above, the selector levers 46 have no normal position and are arranged to be maintained in either operated position until a corresponding code impulse moves them to their alternate position. In order to insure against accidental movement of the selector levers to an alternate position, a latching means is provided as shown in the modified forms in Figures 17 and 18. As shown in these figures, a jocky 46, pivotally mounted on the pin 47'-is normally urged about'the pivot 4' by a compression spring 48'. A projection 49- on the jockey 46engages the edge of the selector lever in one position and the top of the lever in the opposite position. A jockey such as jockey 46' is provided for each of the selector levers and is individual thereto. With the forward selector lever 46 in the position shown in Figure 17, the extension 49" on the jockey 46' engages the edge of the selector lever 46 and the jockey '46 compressin 46' will be rockedcounter'clockwise by action of its spring 48 to press against the top of selector lever 46 and maintain it in its new position. Similarly when the selector lever 46 is rocked to its present position, it will raise g the s ring 48 until its edge passes over the right e ge of the projection 49' to the side as shown and whereupon the compression spring 48'\again rocks the jockey 46 in a counterclockwise direction and the projection 49 will engage the side of the projection of the selector lever 46. In this mannertheselector levers are each held in their operated. position immediately after their operation.

5 Referring again to the first modification, each of the selector levers 46 is provided with a pair of downwardly extending diverging arms 53 and 54 adapted to operatively engage the projections 55 and 56 respec- 9 tively of a transfer T-lever 57 associated with each selector lever 46. Each transfer lever 57 is in alignment with the selector lever 46 above it and is pivotally mounted on a pivot shaft 58 carried by a transfer bail shaft 60, suitably attached to the printer frame. The transfer bail 59 is provided at 'its end with a roller or cam follower 61 and is in operative relation with a main or operating cam 62.

The main or operating cam 62 is located to the rear of the selector cam drum 23 and is mounted on the main shaft 26 for rotatable movement with respect thereto and between the brackets 29 and 30 of the printer frame and comprises internal and external cam surfaces 62 and 62", the transfer bail roller or follower 61 being controlled by the internal cam surface 62. The operating D cam 62 is driven by a friction clutch 63 positioned on the main shaft 26 and to the right of said operating cam, the friction clutch being'substantially identical with the friction clutch 36 described in detail above 5 and comprising friction plates 64 and 65. a drive disc 66, felt friction discs 67, an annular spring 68, spring plate 69 and nut 70, the whole being assembled in the same manner as described above for the friction clutch 36, the friction plate or sleeve 64 being keyed to the main shaft 26 in any desired manner. In order to retain the clutch 63 in position, a spacing sleeve 71 is provided on the main ,.shaft 26 between the friction clutch 63 and anti-friction bearing 28. The operating cam 59, Figure ,2, mounted on the transfer bail 62 is driven by the friction clutch 63 by means of a suitable pin connection 72, Figure 3, positioned between the operating cam 62 and drive disc 66. During predetermined cycles in the operation, the drive disc 66 is held against rotation and cam 62 is therefore stationary. To this end the drive disc 66 has formed on its periphery. adjacent the pin connection 72,a stop lug 73 adapted to be engaged by a trip ball 74 at a certain in- 75 terval in the cycle of' operation of the printer. The trip bail 74 pivotally mounted on transfer bail shaft 60 is'provided with a follower 75, Figure 3, adapted to move on a cam portion provided on the drive disk 38.

'When the clutch 36 has been released and rotatedover a predetermined distance, the follower 75 ridin v over cammed portion of drive disk 38 roc s the bail 74 moving the trip bail out of engagement with stop lug 73.

With the trip bail 74 engaging the stop lug 73, the drive disc 66 will be prevented from turning and will slip relative to rotational movement of, the clutch and accordingly the operating cam 62 will not be rotated. When the trip bail 74 disengages the stop lug 73, the clutch will be released to rotate the operating cam '62.

Slidably mounted on the main shaft 26 and to the left of the operatingcam 62 is a sleeve member 76 operatively connected to the hub of the operating cam 62 by means of interengaging tooth members 77 shown in dotted lines in Fi ure 4. The sleeve member 76 comprises t e sliding element of a toothed 9 or grab clutch 78, the fixed portion 79 of which is keyed to the main shaft 26, directly to the right of the anti-friction bearing 27, Figure 4. Formed on the extreme right edge of the sleeve member 76 is a flange having a side cam surface 80, Figure 2, adapted to engage a fixed cam follower 81, the member 76 being normally held to the right out of engagement with the fixed member 79 against the tension of a coiled spring 82 positioned between the member 76 and the operating cam 62. The initial movement of the operating cam 62 and sleeve member 76 as described above rotate cam 80 until the cam follower 81 rides over the. shoulder of '62 is started slowly at first from power through the friction clutch 63 and after a short initial movement is directly and positively coupled to the drive shaft through the grab clutch. In this manner the advantages of a positive grab clutch connection for transferring power is obtained while at .the same time the shock orjar due to sudden starting by engagement of the teeth 6f such a clutch is obviated through the use of the friction clutch 63. In operation the friction clutch 63 when released as described above, starts the rotation of cams 62 and 80. After cam has rotated a few degrees, the grab clutch 78 engages and carries the cams 62 and 80 nearly to the end of the revolution, when follower 81 rides over the shoulder of cam 80 forcing the sleeve 76 to the right against the action of spring 82 and the clutch member 78 becomes engaged. The friction clutch 63 continues to drive the main or operating cam for the small remainder of the revolution until it is stopped by the stop lug 73 on the drive disc 66 of the clutch 63 striking against the cam release trip bail arm 74.

As the main cam 62 rotates, the transfer bail roller 61 rides over the cammed portion and moves the bail 59 and transfer levers carried thereon forward toward selector levers 46 and as roller 61 reaches the peak of the cam, the transfer levers 57 are forced against'their individual selector levers 46. As the transfer levers 57 engage selector levers 26, they will be rocked about their pivots 58 in either a clockwise or counterclock- -wise direction depending on the setting of the selector levers. If selector lever 46, for example, has been rocked counterclockwise in response to a marking setting of selector cam 45, the arm 54 will engage the extension 56 rocking the transfer lever 57 clockwise as the transfer lever is moved toward the selector levers 46.

Each of the transfer levers 57 is provided with a head '83, Figure 3, projecting into a slot 84 of an individual notched selector disc 85, one such disc being provided for each of the transfer levers 57. Selector discs 85 are freely supported for relative rotation on a sleeve 86, Figure 4, supported in the frame work and are disposed between guiding comb plates 87. The selector disks 85 are provided with V-shaped notches cut along their circumferential edges 88 in a manner well known in the art. As will appear from the following, each disc has two positions. For each combination of setting of these discs, corresponding V-shaped notches on each disc will be in alignment with each other. At right angles to and equally placed around the circumference of the selector discs 85 and guided in slots in the guide plates 87 and a supporting member 90, area series of stop members 89 provided with cam rollers 91. 5 Each of the stop members 89 is pivotally or otherwise carried on the periphery of the supporting member 90 and is formed ,with

two bowed ordepressed portions 92 between the suporting member 90 and the guide plates 0 87, the depressed portions 92 being adapted to receive circular coiled radially contractible springs93, by the action of which stop members 89 are urged into engagement with the V-shaped notches on discs 85. It will be 5 understood however that the members themselves may be constructed of springwire material for this purpose if so desired. As stated above,'for each setting of selector discs 85, one of the stop members 89 will have five of the notches under it in the five discs in alignment and will accordingly be forced by springs 93 into the notches, it being understood by those skilled in the art that only one such alignment of the notches canexist at a time.

W'ith the five discs there are thirty-two possible combinations and accordingly any one of'the thirty-two stop pins can be selected and the typewheel stopped in any one of thirty-two positions. Only thirty-one of these positions are utilized for characters, the thirtysecond position which corresponds to the all marking combinations, having no characters. The stop pin for this position not only stops the type wheel but prevents the tape feed from operating. The typewheel is blank in this position. By the use of a shift mechanism, it is possible to print sixty characters although in the present proposed printer some of these positions are not utilized.

As each of the transfer selectorlevers 57 is rocked about its pivot 58 as described above, it will in turn move the head 83 moving the associated select-or disc 85 to either of its two operative positions. If the transfer lever 57 is rocked clockwise, it will rotate its associated disc 85 counterclockwise. If lever 57 is rocked counter clockwise, it will rotate disc 85 clockwise. As the discs assume new positions, a new alignment of the notches will occur permitting one of the stop pins to drop therein as described above.

, It will be noted from the description thus far given that although the selector cam drum 23 is operated successively, the code impulses are received and in turn successively position the selector levers 46, the transfer operation for setting the selector disks 85 takes place in a single operation as a result of the movement of the transfer levers 57 by 'the transfer bail lever arm 59 operating on the main cam 62. As soon as this transfer has taken place, the selector. levers 46 are free for re-operation in accordance with the new permutation while the selector discs 85 selectively control the operation of the printing mechanism as will now be described.

It will also be noted that the selector levers 46 and selector disks 85 have no normal position but are rocked to their marking or spacing position in accordance with each received code so thatin the event the selector levers are already in the position to which the code impulse. is to operate them, no' operation is necessary, eliminating the number of selector operations necessary. Due to the pivoted arrangements of these members and the absence of means tending to return them to a normal position, it will also be clear that littl e power is necessa operations thereof to heir marking or spacbe firinted.

ing positions.

Attention is also called to the fact that although there are six selector levers 46 there stop arm 94 is secured through the sleeve member 96 to a shaft 97 for rotation therewith. The shaft 97 is mounted in anti-friction bearings 98 and 99 carriedin the ends of the sleeve member 86 which is rigidly se- 90 cured to the printer frame in any suitable manner as for exampleby means of the bolts 100. A spacer sleeve lOl encirclesthe intermediate portion of the shaft 97 and abuts the inner raceways of the anti-friction bearing members 98 and 99. The shaft 97 is driven by means of a worm wheel orgear 102 operatively connected to the motor worm 34. Power is transferred from the motor and gear 102 to the shaft 97 through the drive disc of a friction clutch 103 mounted on. the inner end of the shaft 97. The friction clutch 103 is substantiallyidentical in structure with the friction clutches 36- and 63 described above and comprises a sleeve and friction 88 plate member 104 keyed-inany desired man-- ner to the end of the shaft 97. Slidably mounted on the member 104 is a friction plate member 105, the worm wheel or (gear 102 having friction faces on its sides a apted to engage friction discs 106 positioned on the sleeve 'gagement with the sleeve member 104 retains the friction clutch 103 in operative relation. Disc 108 in threaded engagement with the end of'the sleeve member and locknut 109 serve to regula e the tension on thes ring receive the nut 110 and locknutlllg. The

Worm wheel ortypewheel a'r 102 transfers the power from the motor through thefricbe stoppedrwhen the index or stop arm 94 secured-to the'typewheel shaft 97. engages.

any one of the operated index stop pins 89. As has alreadybeen stated, these arm 94 as it rotates with the typewheel 116. When howeverone of these stop pins isdropped into .a. row of aligned notches of the selector discs 85., this stop pin- 89 movesinto for performing the 107. The end of the shaft 97 is threa ed to .tion clutch 103 to rotate the typewheel I The l6 shaft '97.thus always tends to rotate, but may A I pins; 9 normally extend out of the path ofthe stop 'tion in which the index arm 94 has it when the stop arm 94 reaches it bringing 4 thereat. In this manher the typewheel s aft may be selectively the shaft 97 to a sto stopped at any position in its rotation. With the shaft 97 stationary, the friction clutch .103 will slip, i. e., thegear 102 '-will still rotate due to its direct connection with the motor M.

The typewheel stop arm 94 is equipped with a latch 112 which? passes over the end of the pin 89 which is in the path-of the arm and engages with the opposite side thereof to prevent rebound, when the rotating arm 94 is suddenly brought to a step by eng gement with the operated pin 89. e s show 1n Figures 9 and 10, the latch 112'is pivotally connected to the index stop arm 94 on pm 113 and is retained in alignment with the arm by means of the tension sprin 114- carried by the pin 113. The upper en of the latch 112 terminates in a cam surface 115, Figure 9, so that when the index stop arm 94 engages a stop-89 the latch will ride over the pin 89 against the tension of the spring 114 and the latch will be forced inwardly to engage the other side of the pin after ithas passed said pin to prevent re ound of the index arm 94 as stated above,-

, Secured to and rotatable with shaft 97, in

any suitable manner, is a typewheel 116, Fig" ure 4. The typewheel 116 comprises a cy inder having two individual rows of characters formed on its outer surface as for example letters and numerals. When the index orstop arm 94 engagesa stop pin 89the shaft 97 is brought toa stop and the selected char-.- acter on the typewheel 116 determined by this strip position, may be printed.

aving thus brought the t pewheel 116 to a stop withthe ch racter se ected in operative position so that the prin'tin operation will now described. As alreafiy explained, the typewheel 116 mounted on the opposite end of the typewheel shaft 97 is divided intotwo sections, one containin letters and the other numerals. In 0 rative' relation with the typewheel are the same magebe printed,

raised and press a tape 118 p between a the platen 117 and the wh 116, the printed type being determined by the in sto d in the manner described above e platens 117 secured to a suitable exten sion 119 on the printer frame, are arranged side'by side directly beneath andin opera tive-relationmith the two sections of type on the typewheelllfi Positioned beneath the platens 117 is a rocki two oppositely d' lu 121 and 122 arran (1 thereon and adapted to be selectively responding platen 117 above the leafspring the path of the stop arm 94 Iengage teprintvthe character be 'member 120 having brought-under the letter type. or the numeral type on the typewheel 116'to raise the cordescribed. Member 120 is supported by a pivot post 123 carried on a printing bail 124 and provided with an extension 125 through which it is in operative connection with a member 125. Member 125' has operatively connected thereto a lever 126 which in turn is connected to the sixth T-lever 57.

Member 120 is rocked angularly b member 125 which in turn is operated by t e sixth transfer of T-lever 57 through lever 126 in accordance with the control by the sixth lever 46 in turn positioned by the sixth impulse as described. \Vhen the rocking member 120 is thus actuated as described above and takes an angular position in which the leaf spring 122 is uppermost, a numeral will be printed on the tape. If on the other hand, the sixth impulse is such that member 120 takes the angular position in which the leaf spring 121 is uppermost, a letter will be printed.

The upward movement of the rocking member 120 for actual printing is accomplished thi'ough the printing bail 124 which is pivoted to the frame of the machine and is rocked by the printing follower 127, Figure 1, operated by the channel of the main operative cam 62. As the operating cam 62 is rotating in the manner described above, the printing follower 127 moves to the apex of the cam and rocks the printing bail 124 and through it the rocking member 120 is raised upwardly pressing the tape against the type whee The typewheel as has already been described has previously been brought to a stop at a predetermined position in accordance with the received code. The member 120 has also been rocked in accordance with the sixth or shift pulse and lug spring 121 or 122 is in uppermost position to determine whether a letter or numeral is to be printed. The member 120 is now raised by bail 124 through lug 121 or 122 and presses the tape against the typewheel. After printing, the tape 118 must be moved a distance of one letter space in order to present a fresh surface for printing. To this end a feeding mechanism is provided comprising a wheel 128 in operative relation with a pressure wheel 128 between which the tape 118 is fed. Wheel 128 is attached to the ratchet wheel 129, Figure 1. The ratchet wheel 129 is driven by a pawl 130 actuated by a spring 131. The pawl is withdrawn against its spring tension by a feed bail 132 operated by a cam follower 133, Figure 4, carried on the outer edge of the operating cam 62. In order to properly guide the tape, a tape guide 132 with flanged ends is provided between which the tape moves as it is fed by the feed roller. As will now be clear, the operating cam has three followers, two of which are controlled by the internal cam surface 62 and the third of which is controlled by the external cam surface of the main cam.

It will be noted that immediately after the operating or main cam 62 starts rotating, the

printing bail roller 127 rides to the peak of the cam, thus rocking the printing bail 124 and lifting the rocker member 120 against the printing hammer or platen 117 pressing the tape 118 against the typewheel 116 and printing a character. As the printing bail roller 127 rides down the cam 62, the transfer bail roller 61 is riding up and as it reaches the peak the transfer levers 57 are forced against the selector levers 46 and the selection set up in the selector levers is transferred to the code discs 85.

The transfer of the selector lever settings is thus transferred to the selector discs 85 substantially immediately after printing of the character in accordance with the previous setting. The new alignment of the discs forces out the previously operated stop pin 89 and releases the typewheel shaft for rotation to the .new position determined by the new stop pin in operated position. The printer is thus operated over substantially all of the line time.

While the transfer bail roller 61 is riding to the peak of the internal cam surface 62, the feed bail roller 133 is riding the external cam surface and the motion transmitted operates the feed pawl 130 to engage the next tooth of the feed ratchet. As the roller rides down the cam 62 the feed bail 132 moves the feed bail pawl 130 thus stepping the ratchet 129 one tooth moving the tape 118 forward one letter space. Accordingly the letter spacing operation is prepared during the printing operation and completed immediately after the printing.

The operation of the apparatus thus far describedwill now be given. Assuming that a code is received comprising a start impulse which is always spacing and a code comprising a marking, spacing, marking, spacing and spacing impulse for the first five impulses and a spacing for the sixth impulse.

As already explained, the stop condition is a marking impulse, the armature 5 is to the right and drum 23 is to the left. Arm 24 and lug 25 are in engagement and the clutch 36 is therefore slipping as motor M rotates sleeve 37. In response to a spacing or start impulse, the selector armature 5 is moved to the spacing or to its left position and out of the path of the flutter lever 9, permitting the flutter lever 9 to move by action of its spring 14 in a clockwise direction to in turn move the selector cam drum 23 toward the right. As a result of this longitudinal movement of drum 23, the stop arm 24 disengages the stop lug 25 and initiates the rotation of the selector cam drum 23. At this instant the projection 17 is opposite the corrugation 22, the lever 9 being in its alternate position from that shown in Figure 7. During the next movement, the projection 17 is engaged by corrugation 21 and lever 9 is rocked counter clockwise until the projection 12 is out of the path of armature 5. 1

- The first code impulse being a marking impulse, the selector armature is moved 5 to the marking or ri ht hand side which it is now free to do as t e projection 12 is out of its path. As the flutter cam 19 continues to rotate, projection 18 is engaged by a corrugation 20 and rocks lever 9 clockwise. The

9 flutter lever 9 is however blocked by the selector armature 5 and accordingly the flutter cam'19 is moved to theleft as it rotates. As a result the marking cam on the drum 16 will be moved into line with the marking arm of the first selector lever 46 and will move this lever to the marking position as the cam or drum 23 rotates. 1

The succeeding impulse or second-impulse of the code being a. spacing jimpulse, the selector armature 5, is moved to the left and spacing position and the flutter cam 19 is thus released and the selector cam-drum 23 is permitted to move to the right again.. The sec-' ond spacing cam is thus brought into line with the spacing arm of the second selector lever'46 and as the selector-drum rotates the second selector lever 46 will be moved,to the spacing position. This operation is repeated for the" third, fourth and fifth impulses of this code in the same manner.

. The sixth impulse being a spacing im pulse, consequently the sixth selector lever drum 23 and after the reception of the fourth impulse, the roller of the cam release or trip bail 74 rides into a depression in. the edge of the friction disc 38. -1Thr9ugh the' action of a bail 74 is rocked until it disengages stop 73 and the operating cam62is released. The; operating cam 62 starts to rotate shortly after -theqeception of the fifth impulse and through bail 124 operatesthe printing mechabe the one just selected, but a letter selected by theprevious rotation of the cam drum as ex lained' above. ollowing the sixth impu se,-'the operating 'cam $2 has reached a position at which it 0 rates the transfer bail-59 and the combinationsetup in the selector'levers 46 will be transferred to the' code started'into rotation again-bye impulse,

discs '85. The selectorcam-:druin 23may at this time be at rest as described above or notches in the code disc 85 bein spring this-roller follows the depression, the I nism. However the letter printed will not of the succeeding code. lThe operating cam however continues to rotate, operating the spacing mechanismfor moving the tape to present a new space for printing. Thereafter the camjs stopped as stop -73 engages the cam release bail arm,7 4. v 1

The printing of the letterfor the code, the selection for which has just been described, does not take place until the next selection is'received and the selector cam drum 23 has revolved far enough 'to release the operating cam 62. When the selection has been transferredto the code discs 85, the operation of these discs to their new positions moves the operated pin 89 against which the typewheel sto arm 94 was previously held outwardly an permits the stop arm to rotate untilit strikes against a newly o perated pin 89 which was permitted to move inwardly due to the i in line in this position in accordance with t e new code received.

It will be seen from the above description that a letter which; is selected during one revolution 0f the cam drum is not printed until another revoluti n of the cam drum. In other words, whi eone character is being selected, the preceding character is being printed. A com lete overlap of the apparatus is thus provided and the printer is operatin at all times utilizing the 'filll line time avai able while the code is being received.

In order to maintain the motor in operato normally maintain the motor. non-operat: ing and start in response tocode impulses. To this end, there is mounted on the rear end of the main shaft 26, Figure2, a worm 134 in engagementw'ith a worm wheel 135 pivotally supported on the printer frame inany convenient manner on (pin 136'. Adjacent the worm wheel 135 an 'tion as little as possible, provision is made secured for rotatio'n therewith is a cam 137, Figures 5 and 1 6, sleeved to 'the pin 136. Beneath theQcain' 137 and in operative engagement ,therewith." isa substantially U-shaped lever 138 on fixedpivot 139 and adapted to' .be' rocked there about by the cam "137 againstlthe action offa spring 140 one end of w ich is carried bythe arm and the other'on the frame work in any suitable manner. Pivotall securedvtothe free end of thelevei: 138. y pin 141, is a bell crank'dever 142,- one arm of hieh engages one' of the spring arms 14 of a make andbreak switch, the spring arm 143 and contaet-points 145 and controlling thescircuit of motor M. 1 v

' The other arm '146 of the 142 is in operative relation wi an. armature 147 of a magnet. 148.; Armature 147 moves between two adjustable limit stops 152 and 153'..- Colorized ma et14 is connected .in series with the wind i nguof magnet '1 and is suitably inountedonthe printer frame. The

bell crank lever co-acting spring arm 144 having abutting 5 a contact make and break device 154 and electrical contacts 154. Normally. the magnet 148 in serieswith the magnet 1 operates its armature 147- in response to original line currents.

Normally the apparatus is in'the condition shown in Figure 6; The cammed portion on cam 137 is in engagement with a projection on member 138 and has rocked member 138 about its pivot 139. The magnet 148 at this time holds its armature 147 over to the marking side or full position shown in the path of bell crank 142 so that as member 138 is rocked, the bell crank 142 is rocked about pivot 141 and the two contacts 145 are disengaged. In response to a spacing or start impulse, the armature 147 is operated to the dotted position shown in Figure 8 and the bell crank 142is free to permit the contacts 145 to engage. The motor circuit is thereupon closed and drives pin 136 and earn 137.

As cam 137 is rotatedyits enlarged portion passes over the projection of member 138 and member 138 is rocked by its spring in a clockwise direction about pin 139 to the position shown in Figure 5. In this position. the con-. tacts remain closed irrespective of the position of armature 147. As the cam 137 ro tates it rocks the lever 138 moving the lever 142 vertically from time to time. During each revolution when the raised portion of cam 137 engages member 138 the bell crank is rocked. If, however, a stop or marking impulse is received, the armature 147 of magnet 148 is moved to the full position shown. As the lever 138 is rocked about its pivot 139 at the end of the cycle of operations, the end 146 of the bell crank 142 engages the armature 147 and bell crank 142 is rocked counterclockwise about its pivot 141 causing contacts 145 to dlsengage and opening the C11- cuit of motor M.

. In the above, the electro-magnet 148 con nected in series with the line magnet 1 is shown as a mechanical interference mechanism in which the armature 147 is positioned either in or out of the path of the end 146. of the bell crank 142. In the modifications shown in Figures 19 to 21. the winding 148 is shown as a repeater relay which by means of its armature 147 controls the circuit of a magnet 147'. In this modification. similar numerals are used for equivalent parts shown in the first modification.

In Figures 20 and 21 the magnet 147 is carried on a frame 148' to which is pivoted at 149' an armature 150 j'irovided with an extension 151. A stop 152' limits the movement of the armature 150. A spring 153' normally holds the armature in the non-operated position shown in Figure 21.

The remaining mechanism is similar to that disclosed in connection with the preferred form. As shown, a worm 134 mounted on the rear end of. the main shaft 26, Figure 2, engages with a worm wheel 135, pivotally supported on the frame in any convenientmanner on pin 136. In addition to the worm wheel 135 and rotatable therewith is a cam 137 carried on the pin 136. Beneath the cam 137 and in operative relation therewith is a substantially U -shaped lever 138 on fixed pin 139 arranged to be rocked thereabout by the cam 137 against the action of' a spring 140 one end of which is secured to the arm 138 and the other end to the frame work in any suitable manner. Pivotally secured to the free end of the lever 138 by pin 141 is a bell crank lever 142. one end of which engages one of the spring arms 143 of a make and break switch. the spring arm 143 and (o-acting spring arm 144 having abutting contacts 145 andicontrolling the circuit of the motor M.

The other arm 146 of the bell crank lever 142 is in operative relation with the projection 151 on the armature 150' of the-magnet 147.

Normally the apparatus is in the condition sh own in Figure 19. The shoulder of the cam 137 has previously engaged the projection on the lever 138 and has rocked the latter about its pivot 139. .At this instant the received signal is a stop or marking impulse which operates the line magnet 1 and the relay 148. The armature 147 of relay 148 is moved to engage its contact as shown in Figure 19 and. a circuit is thereupon completed for the magnet 147' from the ne ative side of battery through the lower winding of the magnet 147, the armature of relay 148 in engagement with its contact to the upper winding of the magnet 147' to the positive side of battery. The magnet 147' is thus energized and operates itsarmature 150 against the tension of the spring 153 until the projection 1.51 is in engagement with the extension 146 of the bell crank 142 as shown in Figure 19. Accordingly as the lever 138 is rocked about pivot 139 as stated above, the bell crank 142 is rocked in a counter clockwise direction about its pivot 141 and moves the spring arm 143 as shown to disengage the contacts 145. thus opening the circuit of the motor M.

In response-to a start or spacing impulse, the line magnet 1 operates as indicated above and simultaneously the relay 148 is deenergized whereupon armature 147 is restored to its normal position disengaging its contact and the circuit of the winding of the magnet 147 is opened. The magnet 147 is deenergized and the spring 153' rocks the armature 150' about the pivot 149' to disengage the extension 146 of the bell crank 142. The

spring contact arm 143 thereupon rocks the has passed the projection on. lever 138 the lever 138 is moved upwardly by its spring as described above and thereafter the contacts 145 remain closed independently of energization or deenergization of magnet 147". The

m above cycle of operation is then repeated when acomplete revolution has been completed and the shoulder on the cam 137 again engages the projection on lever 138. I Figures 11 and 12 are schematic diagrams of preferred circuit connections. In Figure 11, the signalling line 156 is shown connected to the terminal jacks 157 and 158 rovided with "connections; 159 and 161. hese are shown separated from the jacks at the left thereof for purposes of-illustration. But it will be understood that normally these are secured inthe jacks. Extending from-connection 159 is a conductor 162 which extends to the connecting strap 163 on the terminal block 8. The strap 163 communicates through conductor 165 to one of the-selector coils 3 of the selector magnet 1. The other terminalof this coll extends over the conductor 167 to the second conductor strap 168 on the ter- 80 minalblock 8'. Similarly the second winding 4 of ,the selector magnet 1 is connected over conductors 171 and 172 to the conductor straps 173 and 174 respectively; Conductor strap 173 is connected over the conductor 175 85 through the terminal connector 176 to the coil 177 of the motor control relay 148, the other terminal of which extends overs the conductor 178 to the terminal 161 connected to the positive side of the signalling line 156. With the circuit connections, as shown, coils 3 and 4 of the selector magnet 1 may be connected either in series or in parallel. :In order to connect the coils in series, the rings 168 and 174 are jumped as shown in the preferred em-' bodiment. In order to connect these coils in I parallel, it is merely necessary to jump the straps 173 to 168 and the ring 174 to ring 163.

As described heretofore, the motor control relay 148, controls motor control contact 147 to engage its contact 145 when the relay is en- The armature circuit extends through the resistance 182, conductor 185 to the other side of the armature 151,,the opposite terminal being connectedfto conductor 184. The conductor 184'extends to thepower swimh'186 which may be of any welldtnown construction, operable to one of either of two positions inwliich it remains set the one position being an open circuit in which the circuit is opened and the second a closing circuit. The opposite terminalof the power switch extends through fuses 187 to a direct current source of power '188; The opposite side of this source of power extends over the conductor, 189 to a one-half microfarad condenser 191 connected in the circuit and shunting the motor control contacts. to prevent arcing thereon during operation. The operation of the apparatus will be obvious from the above description. When impulses are received' which operate the selectorcoils, these also flow in series through the motorcontrol relay 177, which in turn on operating its contact, as described in de tail above, closes the motor circuit which is thereupon started into operation for driving theprinter to operate during the .impulsing period.

In Figure 12, the circuit connection when. an alternating current motor is employedis disclosed. Similar characters are employed for similar parts. It will be noted that the circuits are substantiallythe same except (for the details of the motor circuit. The motor control contact 145 is connected over conductor 181 to the two resistances 182 connected in parallel across the circuit instead of in series as shown in the direct current system. A circuit then extends in multiple through. the governor control contact 183 and through the field winding 150 and armature winding 151- in series to the opposite side ofthe alternating current source over conductor 184. With the exception of this difference in circuit construction, 'the similar arrangement is employed.

The principles and desirable features here described are likewise applicable to a wide range of selecting mechanisms and other devices.

What we claim as new is:

1. A selector mechanism comprising a cam drum, means for rotating said cam drum,

-' 2. A selector mechanism comprising'a cam,

/ drum, means for rotating said cam drum, and

means whereby said first mentioned means also operates said cam drum' longitudinally, said last mentioned movement of said cam drum being selectively controlled in-accordance with received code'combinations of im: pulses.

3. A selector mechanism comprising a cam drum, means for rotating said cam drum, means whereby said first mentioned means also operates said cam drum longitudinally,

and means for selectively controlling said last mentionedmovement of said drum in ac- Ill cordance with received code combinations of impulses.

4. In a selector mechanism, a cam drum, a source of power for rotating said cam drum, cam mechanism carried b said drum, and means cooperating with sald cam mechanism for translating the rotary motion of said first mentioned power means to move said drum longitudinally.

5. In a selector mechanism, a cam drum, a source of power for rotatin said cam drum, a cam carried by said cam rum, means cooperating with said cam for translating the rotary motion of said first mentioned power means to move said cam drum longitudinally, and means responsive to received code combinations of impulses for controlling said last mentioned movement of said cam drum.

6. In a selector mechanism, a cam drum, a flutter cam carried on said cam drum, a flutter lever cooperating with said flutter cam for moving said cam drum to predetermined positions, means for rotating said cam drum, and electromagnetic means responsive to received code combinations of im ulses and controlling the operation of said utter lever for variably operating said cam drum longitudinally in accordance with received code combinations of impulses.

7 In a selector, a rotating cam drum, means for moving said cam drum longitudinally, and means responsive to received code combinations of impulses for ermitting or preventingsaid movement of said cam drum.

8Q In a selector, a cam drum, a motor for rotating said cam drum and for moving said cam drum longitudinally, and electromagnetic means responsive to received code combinations of impulses for preventing or permitting such longitudinal movement of said cam drum in accordance with received cod combinations of impulses. I

combinations of impulses, and means dependent upon the energizatibn of said electromagnet but otherwise functioning independently thereof for operating said pin barrel longitudinally.

11. In a selector apparatus, an electromagnet responsive to received code combinations the energization of said electrom'aget, and

selector mechanism variably operated in accordance with the operation of said armature.

12. In a selector apparatus, an electromagnet responsive to received code combinations of impulses, an armature therefor, said armature being unimpeded during each impulsing period for movement in accordance with the energization of said electromagnet, selector mechanism, and means for variably operating said selector mechanism in accordance with the operation of said armature.

13. In a selector apparatus, a rotatable distributor mechanism, a source of power for driving said distributorimechanism, an electromagnetic means for controlling the appli-.; cation of said source of power to said distributor, said electromagnetic means being respon-' sive to a received impulse for permitting the application of said source of power to said distributor whereby said distributor is rotated in synchronism with received impulses.

14. In combination, a plurality of selector mechanisms, a second set of selector-mechanisms individual to each of said first selector mechanisms, a shift mechanism and means for operating said second set of selector mechanisms in accordance with the operation of said first selector mechanisms and for simultaneously operating said shift mechanism in accordance with the operation of one of said selector mechanisms.

15. In combination, a luralityof selector levers, a sixth pulse se ector lever, a plurality of second selector levers, one for each of said first selector levers, and shift mechanism 'for operating said second .selector levers in accordance with the operation of said first mentioned selector levers and for simultaneously operatin said shift mechanism in accordance wit the operation of said sixth pulse selector lever.

16. In a selector apparatus, a plurality of pivoted selector levers, means responsive to code combinations of impulses for variably operating said selector levers, a sixth pulse selector lever, a 'plurality of second selectors one individual to each of said first set of selector levers, a shift'mechanism, and means for operating said second selector levers in accordance ,with the operation of said first selector levers and for operating said shift mechanism in accordance with the operation Y of said sixth pulse lever.

17 In a selector mechanism, a pin barrel selector, markmg and spacing cams on said p n barrel selector, selector levers, one for each pair of marking and spacing cams, said selector levers being arranged to be operated by their individual pairs of cams in accordance with the operation of said pin barrel as said cams come into operative relation with said selector levers.

18. In a selector mechanism, a plurality 

